Highly cascaded first-order fiber Bragg gratings in highly multimode optical fibers for distributed temperature sensing under harsh environment conditions

Author

Farhan Mumtaz, Missouri University of Science and TechnologyFollow
Hanok Tekle
Bohong Zhang
Jeffrey D. Smith, Missouri University of Science and TechnologyFollow
Ronald J. O'Malley, Missouri University of Science and TechnologyFollow
Rex Gerald, Missouri University of Science and TechnologyFollow
Jie Huang, Missouri University of Science and TechnologyFollow

Abstract

This study presents a pioneering technique for fabricating highly cascaded first-order fiber Bragg gratings (FBGs) using a femtosecond laser-assisted point-by-point inscription method in highly multimode optical fibers, specifically Sapphire crystalline fiber, and pure silica coreless fiber. Notably, it marks the first successful demonstration of a distributed array comprising 10 FBGs within highly multimode fibers. This achievement is facilitated by a high-power laser technique that yields larger reflectors characterized by a Gaussian intensity profile. These first-order FBGs offer various advantages, including enhanced reflectivity, reduced fabrication time, and simplified spectral characteristics, enhancing their accessibility for interpretation when contrasted with higher-order FBGs. In addition to that it encompasses a comprehensive analysis of the robustness and efficacy of these FBGs, with particular emphasis on their ability to endure extreme temperatures. These FBGs demonstrate an advantageous capability for localized multi-point temperature monitoring, reaching temperatures up to 1500°C with sapphire crystalline fiber and 1100°C with pure silica coreless fiber. This resilience makes them suitable for deployment in harsh environmental conditions. This innovative approach substantially broadens the potential applications of highly multimode optical fibers, particularly in the arena of sensing and communication, where challenges related to thermal gradients and harsh environments prevail. These groundbreaking first-order FBGs signify a substantial advancement in the realm of distributed temperature sensing, offering supreme capabilities for temperature monitoring and signal stability. As such, our work holds the promise of a substantial impact on industries and applications that demand unwavering reliability under extreme conditions.

Recommended Citation

Farhan Mumtaz, Hanok Tekle, Bohong Zhang, Jeffrey D. Smith, Ronald J. O'Malley, Rex E. Gerald II, and Jie Huang "Highly cascaded first-order fiber Bragg gratings in highly multimode optical fibers for distributed temperature sensing under harsh environment conditions", Proc. SPIE 13044, Optical Waveguide and Laser Sensors III, 130440F (7 June 2024); https://doi.org/10.1117/12.3013985

Department(s)

Materials Science and Engineering

Second Department

Electrical and Computer Engineering

Keywords and Phrases

Fiber Bragg gratings, Sapphire, Multimode fibers, Reflectivity, Fabrication, Optical fibers, Femtosecond phenomena

Document Type

Conference proceedings

Document Version

Citation

File Type

text

Language(s)

English

Rights

© 2024 Society of Photo-Optical Instrumentation Engineers (SPIE)

Publication Date

7 June, 2024